ES2678196T3 - Routing method and automatically switched optical network - Google Patents

Abstract

A rerouting method, comprising: determining (101), by a first network element of an automatically switched optical network, ASON, whether a network element connected to the first network element of the ASON is a network element of the network of a third party and/or a network element of the conventional network; configuring (102), by the first ASON network element, a first joint connection monitoring level, TCM, available to a higher order optical channel data unit k layer of the first ASON network element if the network element connected to the first network element of the ASON is a network element of the third-party network and/or a network element of the conventional network, where the first level of TCM is the same as or different of a second level of TCM configured by a second network element of the ASON, and the network element of the third party network and/or the network element of the conventional network is connected between the first network element of the ASON and the second network element of the ASON; monitoring (103), by the first ASON network element, in accordance with the first TCM level, whether a link between the first ASON network element and the second ASON network element fails; and initiating (104), by the first ASON network element, rerouting if the link between the first ASON network element and the second ASON network element fails; wherein determining, by a first network element of an automatically switched optical network, ASON, whether a network element connected to the first network element of the ASON is a network element of a network element of the network of a third party and/or a network element of the conventional network comprises: sending (201), by the first network element of the ASON, using the overhead of an optical channel transport unit layer k, a first identifier to the network element connected to the first network element of the ASON; determining (202), by the first network element of the ASON, whether the overhead of an optical channel transport unit layer k of the network element connected to the first network element of the ASON can receive the first identifier; if the first network element of the ASON determines that the optical channel transport unit layer k overhead of the network element connected to the first network element of the ASON cannot receive the first identifier, send (203), for part of the first network element of the ASON, using the overhead of an optical channel data unit layer k, a second identifier to the network element connected to the first network element of the ASON, where the first identifier is the same than or different from the second identifier; and determining (204), by the first network element of the ASON, whether the optical channel data unit layer k overhead of the network element connected to the first network element of the ASON can receive the second identifier, and if the optical channel data unit layer k overhead of the network element connected to the first network element of the ASON can receive the second identifier, determining that the network element connected to the first network element of the ASON is a network element of the third party network and/or a network element of the conventional network.

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DESCRIPTION

Routing method and automatically switched optical network Technical field

The embodiments of the present invention are related to optical communications technologies and, in particular, to a re-routing method and an automatically switched optical network.

Background

At present, in a conventional optical transport network (OTN) a control plane is introduced to form an automatically switched optical network (ASON), thus implementing an automatic routing configuration, end-to-end service maintenance, automatic recovery network, etc. As technologies develop, in today's networks there is a hybrid interconnection mode of an OTN and an ASON. For a clear description below, referring to an ASON provided by the same manufacturer, an OTN provided by the same manufacturer is called a conventional network, and an OTN and an ASON provided by different manufacturers are called third-party networks. Some adjacent ASONs from the same manufacturer are connected using a third-party network. In general, when a link from a third-party network fails, a fault alarm is transmitted using the overhead of the optical channel transport unit (OTUk) layer. However, the regeneration of an alarm in the OTUk layer is terminated at both ends of a physical layer. That is, the alarm cannot be transmitted to the OTUk layer of an ASON using the overhead of an OTUk layer of a third-party network and, therefore, the ASON cannot detect the failure of a network link of a third-party network. third, and rerouting cannot be initiated quickly to recover a connection, thereby causing a service interruption.

In the prior art, in order to prevent an ASON from detecting the failure of a link from a third party network, the link failure is transmitted using the overhead, which can pass through the network of a third party. , of a layer of optical channel data unit k (ODUk). If a fault occurs, rerouting begins.

However, in the process of transmitting the failure of a third-party network link using the OTUk layer overhead, it is necessary that a first node and a last node of the service perform a packet exchange, in order to determine if the link failure is due to a link failure between the first node and the last node. Only rerouting starts if the link failure is due to the link failure between the first node and the last node. If the startup speed is low, the link cannot be recovered quickly, and finally the problem arises that the quality of service cannot be assured.

Document US 2012/0106948 A1 shows an optical network and a signaling of the control plane within the optical network and the TCM monitoring on different equipment manufacturers.

In addition, EP 1 422 968 A1 shows a method of troubleshooting in optical networks.

In addition, EP 1 981 211 A1 also shows a method for processing the dependence of joint connection monitoring failure of different levels and associated equipment. It only deals with conventional optical networks. It does not show the use of ASON network elements.

In addition, EP 1 916 799 A1 also addresses optical networks. Especially, it shows a method to automatically implement a joint concatenation monitoring and associated equipment. Although it only deals with conventional optical networks. It does not show the use of ASON network elements.

EP 2 296 300 A1 shows a method and equipment for automatic discovery in optical transport networks.

Summary

The embodiments of the present invention provide a rerouting method and an automatically switched optical network, which implements that, in a hybrid interconnection mode of an ASON and a third party network, rerouting is performed quickly when the network fails. from the third party, in order to retrieve a link and ensure the quality of service.

According to a first aspect, one embodiment of the present invention provides a rerouting method, which includes:

determine, by a network element of an automatically switched optical network (ASON), whether a network element connected to the first ASON network element is a network element of a third party network and / or an element of network of a conventional network;

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configure, by the first ASON network element, a first level of joint connection monitoring (TCM) available for a higher order optical channel data unit layer k of the first ASON network element if the element A network element connected to the first ASON network element is a network element of a third party network and / or a network element of a conventional network, where the first level of TCM is the same or different from a second level of TCM configured by a second ASON network element, and the network element of a third party network and / or the network element of the conventional network is connected between the first ASON network element and the second network element. ASON network;

monitor, by the first ASON network element, according to the first level of TCM, if a link between the first ASON network element and the second ASON network element fails; and

initiate, by the first ASON network element, rerouting if the link between the first ASON network element and the second ASON network element fails.

In addition, the determination, by a first network element of an automatically switched optical network (ASON), of whether a network element connected to the first ASON network element is a network element of a third-party network and / or a network element of a conventional network includes:

sending, by the first ASON network element, using the overhead of an optical channel transport unit layer k, a first identifier to the network element connected to the first ASON network element;

determining, by the first ASON network element, whether the overhead of an optical channel transport unit layer k of the network element can receive the first identifier;

if the first ASON network element determines that the overhead of the optical channel transport unit layer k of the network element cannot receive the first identifier, send, by the first ASON network element, using the overhead of an optical channel data unit layer k, a second identifier to the network element connected to the first ASON network element, where the first identifier is the same or different from the second identifier; Y

determine, by the first ASON network element, whether the overhead of the optical channel data unit layer k of the network element can receive the second identifier, and whether the overhead of the data unit unit layer k of Optical channel of the network element may receive the second identifier, determine that the network element is a network element of a third party network and / or a network element of a conventional network.

In a first possible way of implementing the first aspect, the configuration, by the first ASON network element, of a first level of joint connection monitoring (TCM) available for an optical channel data unit layer k of higher order of the first ASON network element if the network element connected to the first ASON network element is a network element of a third party network and / or a network element of a conventional network includes:

sending, by the first ASON network element, using the first level of TCM, a third identifier to a higher order optical channel data unit layer k of the second ASON network element; Y

determine, by the first ASON network element, whether the upper order optical channel data unit layer k of the second ASON network element can receive the third identifier, and if the third identifier can be received, determine that the first TCM level is available.

With reference to the first aspect or to the first possible way of implementing the first aspect, in a second possible way of implementing the first aspect, before the start, by the first ASON network element, of the re-routing if the link between the First ASON network element and the second ASON network element, the method also includes:

determine, by the first ASON network element, whether the upper order optical channel data unit layer k of the first ASON network element can receive a fourth identifier that is sent by the second network element of ASON using the second level of TCM; Y

if the fourth identifier can be received, monitored, according to the second level of TCM, if a link between the second ASON network element and the first ASON network element fails.

According to a second aspect, one embodiment of the present invention provides a network element of an automatically switched optical network (ASON), which includes:

a determination module, configured to determine whether a network element connected to the ASON network element is a network element of a third party network and / or a network element of a conventional network;

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a configuration module, configured for, when the determination module determines that the network element connected to the ASON network element is a network element of a third party network and / or a network element of a conventional network, set up a first level of joint connection monitoring (TCM) available for a higher order optical channel data unit layer k, where the first level of TCM is the same or different from a second level of TCM configured by a second element of the ASON network, and the network element of a third party network and / or the network element of the conventional network is connected between the network element of the ASON and the second network element of the ASON;

a monitoring module, configured to monitor, according to the first level of TCM configured by the configuration module, if a link between the ASON network element and the second ASON network element fails; Y

a start module, configured to initiate rerouting when the monitoring module detects that the link between the ASON network element and the second ASON network element fails.

The ASON network element also includes:

a sending module, configured to send, using the overhead of a layer of optical channel transport unit k, a first identifier to the network element connected to the ASON network element, where

The determination module is also configured to determine whether the overhead of an optical channel transport unit layer k of the network element can receive the first identifier sent by the sending module;

the sending module is also configured for when the determination module determines that the overhead of the optical channel transport unit layer k of the network element cannot receive the first identifier, send, using the overhead of a layer of optical channel data unit k, a second identifier to the network element connected to the ASON network element, where the first identifier is the same as or different from the second identifier; Y

the determination module is specifically configured for, when it is determined that the overhead of a layer of optical channel data unit k of the network element can receive the second identifier, determine that the network element is a network element of the network of a third party and / or the network element of a conventional network.

In a first possible way of implementing the second aspect, the sending module is specifically configured to send a third identifier to a higher order optical channel data unit layer k of the second ASON network element using the first level of TCM; Y

the determination module is also configured for, when it is determined that the upper order optical channel data unit layer k of the second ASON network element can receive the third identifier configured by the configuration module, determine that The first level of TCM is available.

Referring to the second aspect or a first possible form of implementation of the second aspect, in a second possible form of implementation of the second aspect, the determination module is also configured to, before the start module starts the rerouting, determine if the upper order optical channel data unit layer k of the ASON network element can receive a fourth identifier sent by the second ASON network element using the second level of TCM; Y

The monitoring module is also configured for when the determination module determines that the higher order optical channel data unit layer k of the ASON network element can receive the fourth identifier sent by the second network element. of the ASON using the second level of TCM, monitor, according to the second level of TCM, if a link between the second network element of the ASON and the network element of the ASON fails.

According to a third aspect, an embodiment of the present invention provides an automatically switched optical network (ASON) network element, which includes a processor and a memory, where the memory stores an execution instruction, and when executes the ASON network element, the processor communicates with the memory, and the processor executes the execution instruction to allow the ASON network element to execute the method according to the first aspect and the first or the second possible way of implementing the first aspect.

According to the rerouting method and the automatically switched optical network provided in the embodiments of the present invention, after determining that a network element connected to a first ASON network element is a network element of a third party network and / or a network element of a conventional network, the first ASON network element configures a first level of

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TCM; and monitors, according to the first level of TCM, if a link between the first ASON network element and a second ASON network element fails. When a fault is found, rerouting is initiated to retrieve the link, which allows, in a hybrid interconnection mode of an ASON and a third party network, rerouting is performed quickly when a third party network fails, so that the link is recovered and the quality of service is ensured.

This invention is defined only by the appended claims. Embodiments that are not within the scope of the appended claims will be understood to be only useful examples for understanding the invention.

Brief description of the drawings

FIG. 1 is a diagram of a network architecture applicable to a rerouting method in accordance with the present invention;

FIG. 2 is a flow chart of a first embodiment of a rerouting method according to the present invention;

FIG. 3 is a flow chart for identifying a type of network element in a rerouting method in accordance with the present invention;

FIG. 4 is a diagram of the structure of levels based on an OTN in accordance with the present invention;

FIG. 5 is a diagram of another network architecture applicable to a rerouting method in accordance with the present invention;

FIG. 6 is a schematic diagram of the structure of a first embodiment of an ASON network element in accordance with the present invention;

FIG. 7 is an additional schematic diagram of the structure of an embodiment of an ASON network element in accordance with the present invention; Y

FIG. 8 is a schematic diagram of the structure of a second embodiment of an ASON network element in accordance with the present invention.

Description of the modes of realization

In order to make the objectives, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions described in the embodiments of the present invention are described in a clear and complete manner by referring to the attached drawings in the embodiments of the present invention. Obviously, the embodiments described are a part instead of all the embodiments of the present invention. All other modes of realization obtained by a person with a normal knowledge in the art based on the modes of realization of the present invention without creative efforts will be considered within the scope of protection of the present invention.

FIG. 1 is a diagram of a network architecture applicable to a rerouting method according to the present invention. As shown in FIG. 1, a network element of a third party network and / or the network element of the conventional network is connected between network elements of an ASON provided by the same manufacturer, where the network element of the conventional network is an element OTN network element provided by the same manufacturer, and the network element of a third party network is an OTN network element or an ASON network element provided by a different manufacturer. A service flow from a client side such as an Internet Protocol (IP) network, a Multiprotocol Label Switching (MPLS) network, or an Ethernet crosses a first ASON network element and an element network of a conventional network and / or a third-party network element, and reaches a second ASON network element; or a service flow crosses a second network element of the ASON and a network element of a conventional network and / or a network element of a third party, and reaches a first network element of the ASON. In order to ensure the quality of a service transmission, when a link between the first ASON network element and the second ASON network element fails or when a link between the second ASON network element fails and the first network element of the ASON, it is necessary to quickly perform a re-routing in order to recover the link, thus ensuring the quality of service.

It should be noted that FIG. 1 only shows two network elements of an ASON, and in a real network, the first ASON network element and the second ASON network element can also be connected to an ASON network element or a network element. network of a third party network, a network element of a conventional network, etc.

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FIG. 2 is a flow chart of a first embodiment of a rerouting method according to the present invention. This embodiment is applicable to a scenario in which, in a hybrid network mode of an ASON and a third-party network, it is necessary to quickly re-route when a third-party network fails. Specifically, this embodiment includes the following steps:

101: A first network element of an automatically switched optical network (ASON) determines whether a network element connected to the first ASON network element is a network element of a third party network and / or a network element of a conventional network

Referring both to FIG. 1 as in FIG. 2, in this embodiment, the first ASON network element automatically identifies the type of network element connected to the first ASON network element. That is, it is identified if the network element connected to the first ASON network element is an ASON network element provided by the same manufacturer, or a network element of a third party network and / or an element of network of a conventional network. For example, in each network element of the ASON a table can be previously established, in the preset table the information about another network element connected to the ASON network element is registered, and the first ASON network element can be Identify, according to the preset table, the type of network element connected to the first ASON network element.

102: If the network element connected to the first ASON network element is a network element of a third party network and / or the network element of a conventional network, the first ASON network element configures a first Joint connection monitoring level (TCM) available for a higher order optical channel data unit layer k of the first ASON network element, where the first level of TCM is the same or different from a second level of TCM configured by a second network element of the ASON, and the network element of the network of a third party and / or the network element of the conventional network is connected between the first network element of the ASON and the second network element of ASON.

In general, an ODUk layer has six different TCM levels, called TCM 1 through TCM 6. Using the TCM levels, real-time monitoring of a connection status of the ODUk layer is completed. In this step, if the first network element of the ASON determines that the network element connected to the first network element of the ASON is a network element of the network of a third party, the first network element of the ASON configures the first level of TCM available for the higher order ODUk layer of the first ASON network element.

Optionally, in this step, the first ASON network element sends a third identifier to a higher order optical channel data unit layer k of the second ASON network element using the first level of TCM, and the first ASON network element determines whether the upper order optical channel data unit layer k of the second ASON network element can receive the third identifier. If the third identifier can be received, the first level of TCM is available.

Specifically, the first ASON network element may attempt to send the third identifier to the higher order ODUk layer of the second ASON network element using TCM levels one by one starting from TCM 1, and determine if the The higher order ODUk layer of the second ASON network element can receive the third identifier. If the third identifier can be received, this indicates that the first level of TCM is available; otherwise, another level of TCM is used to make another attempt.

103: The first ASON network element monitors, according to the first level of TCM, if a link between the first ASON network element and the second ASON network element fails.

After determining the availability of the first level of TCM, the first ASON network element starts the TCM monitoring, in order to monitor if the link between the first ASON network element and the second network element of the network fails. the ASON, that is, to monitor if a link of the network element of a third party network and / or the network element of the conventional network fails.

104: If the link between the first ASON network element and the second ASON network element fails, the first ASON network element initiates rerouting.

When TCM monitoring is used and it is determined that the link between the first ASON network element and the second ASON network element fails, the first ASON network element initiates rerouting to retrieve the link.

According to the rerouting method provided in this embodiment of the present invention, after determining that a network element connected to a first ASON network element is a network element of a third party network and / or a network element of the conventional network, the first ASON network element configures a first level of TCM; and monitors, according to the first level of TCM, if the link between the first ASON network element and the second ASON network element fails. When it is determined that the link fails, a rerouting begins to retrieve the link, which

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implements that, in a hybrid network mode of an ASON and a third-party network, when the network of a third party fails, rerouting is performed quickly, in order to recover the link and ensure the quality of service.

In the first embodiment above, the first ASON network element identifies, according to the following process, the type of network element connected to the first ASON network element. For details, see FIG. 3. FIG. 3 is a flowchart identifying the type of a network element in a rerouting method according to the present invention, which includes the following steps:

201: A first ASON network element sends, using the overhead of an optical channel transport unit layer k, a first identifier to a network element connected to the first ASON network element.

In general, an ASON based on an OTN also has the OTN level structure. In FIG. 4 details are shown. FIG. 4 is a diagram of the level structure based on an OTN in accordance with the present invention.

Referring to FIG. 4, an optical service channel (OPUk) k layer is encapsulated as a payload, a service flow from a client side such as an IP network and an MPLS network; an OPUk with the header overhead is added and encapsulated in an ODUk layer; the ODUk is added with the header overhead and a destination error correction code (FEC) and encapsulated in an OTUk layer; an electro-optical conversion is performed in the OTUk layer, and the signal becomes an optical channel signal (OCH); then, the multiple OCH signals are multiplexed as a multiplex optical section (OMS); and, finally, WHO is added with the overhead to become an optical transmission section (OTS). In general, in the industry, an ODUk layer network is called an electrical layer network and an OCH layer network is called an optical layer network.

In this step, an electrical layer network of the first ASON network element sends the first identifier, that is, the first ASON network element sends, using the OTUk layer overhead, the first identifier to the network element connected to the first ASON network element. The first identifier can be a custom identifier or a preset identifier, for example, "OTUk SM TTI".

202: The first ASON network element determines whether the overhead of a layer of optical channel transport unit k of the network element receives the first identifier.

The first ASON network element determines whether the overhead of an OTUk layer of the network element connected to the first ASON network element can receive the first identifier. For example, the first ASON network element determines whether a correct response can be received within a predetermined time, where the correct response is sent using an IP network and the like by the network element connected to the first network element. the ASON. If the correct answer can be received, step 205 is executed, in order to determine that the network element connected to the first ASON network element is an ASON network element of the same manufacturer; If the first ASON network element cannot receive the correct response, step 203 is executed.

203: The first ASON network element sends, using the overhead of a layer of optical channel data unit k, a second identifier to the network element connected to the first ASON network element, where the first identifier is the same or different from the second identifier.

If the first ASON network element determines that the OTUk layer overhead of the network element cannot receive the first identifier, the first ASON network element sends, using the ODUk layer overhead, the second identifier to the network element connected to the first ASON network element, where the first identifier is the same or different from the second identifier, for example, "ODUk PM TTI".

204: The first ASON network element determines whether the overhead of an optical channel data unit layer k of the network element can receive the second identifier, and whether the overhead of the optical channel data unit layer k of the network element may receive the second identifier, determine that the network element is a network element of a third party network and / or a network element of the conventional network.

After sending the second identifier, the first ASON network element continues to determine if the ODUk layer overhead of the network element connected to the first ASON network element can receive the second identifier. If the ODUk layer overhead of the network element connected to the first ASON network element can receive the second identifier, step 206 is executed and this indicates that the network element is a network element of a third-party network and / or a network element of the conventional network; otherwise, step 207 is executed.

It should be noted that since the second identifier is transmitted using the ODUk layer overhead, and the information and the like associated with the ODUk layer overhead can be transmitted transparently, it cannot be transmitted.

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it can determine, depending on whether the overhead of the ODUk layer of the network element connected to the first network element of the ASON can receive the second identifier, that the network element connected to the first network element of the ASON is an element of network of a third party network and / or a network element of the conventional network. However, the first identifier is transmitted using the OTUk layer overhead, and the information and the like associated with the OTUk layer overhead cannot be transmitted transparently. That is, if between the first network element of the ASON and the network element of the network of a third party and / or the network element of the conventional network there is another network element of the ASON, and the network element of the ASON, the first network element of the ASON and a second network element of the ASON belong to the network elements of the same manufacturer, the first identifier cannot reach the second network element of the ASON through another element ASON network, or the network element of a third party network and / or the network element of the conventional network. Therefore, in order to determine precisely whether the first ASON network element and the second ASON network element are connected through the network element of a third-party network and / or the element Conventional network network, steps 202 to 204 above need to be executed in a strict sequence.

205: Determine that the network element connected to the first ASON network element is an ASON network element from the same manufacturer.

206: Determine that the network element connected to the first ASON network element is a network element of a third party network and / or a network element of the conventional network.

207: Stop detection.

After sending the second identifier, the first ASON network element continues to determine if the ODUk layer overhead of the network element connected to the first ASON network element can receive the second identifier. If the ODUk layer overhead of the network element connected to the first ASON network element cannot receive the second identifier, this indicates that the second ASON network element does not exist, or the network element of the network. a third party or the network element of the conventional network is connected only to the first network element of the ASON and is not connected to the second network element of the ASON. In this case, the detection stops, and the next detection starts periodically.

Optionally, in the first embodiment above, in addition to monitoring, according to the first level of TCM, if the link between the first ASON network element and the second ASON network element, the first element of the network fails The ASON network can also determine if a higher order ODUk layer of the first ASON network element can receive a fourth identifier sent by the second ASON network element using a second level of TCM, and if it can be received the fourth identifier, monitor, according to the second level of TCM, if the link between the second network element of the ASON and the first network element of the ASON fails. For example, the link between the first ASON network element and the second ASON network element is called a direct link, and the link between the second ASON network element and the first ASON network element is called reverse link. The first ASON can configure a first level of available TCM for the ODUk layer of the first ASON network element and monitor, according to the first level of TCM, if the direct link fails. The second ASON network element can also configure a second level of TCM available for the ODUk layer of the second ASON network element. In this way, the first ASON network element can monitor, according to the second level of TCM, if the reverse link fails. The first level of TCM may be the same or different from the second level of TCM. For example, both the first level of TCM and the second level of TCM can be a TCM 3, or the first level of TCM is a TCM 1 and the second level of TCM is a TCM 5.

In general, k in an OTUk indicates the level of a rate, and k = 1, 2, or 3. If k = 1, it indicates that the rate is 2.5 Gbit / s. If k = 2, it indicates that the rate is 10 Gbit / s. If k = 3, it indicates that the rate is 40 Gbit / s. Next, an ODU2 is used as an example, that is, it is assumed that rates of all 10 Gbit / s links are used as an example to describe the present invention in detail. Specifically, see FIG. 5.

FIG. 5 is a diagram of another network architecture applicable to a rerouting method in accordance with the present invention. As shown in FIG. 5, a first ASON network element, a second ASON network element, a third ASON network element and a fourth ASON network element are ASON network elements provided by the same manufacturer. The first network element of the ASON and the second network element of the ASON are connected using a network element of the third party network and / or a network element of the conventional network, that is, a port A of the The first network element of the ASON is connected to a port E of the network element of a third party network and / or the network element of the conventional network; a port B of the first network element of the ASON is connected to the third network element of the ASON; a port C of the second network element of the ASON is connected to a port F of the network element of the network of a third party and / or the network element of the conventional network; and a D port of the second ASON network element is connected to the fourth ASON network element. He

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port A, port B, port C, port D, port E and port F are, for example, ports used to connect to an OTUk layer.

Referring to FIG. 5, a specific process of this embodiment is as follows:

First, all network elements of an ASON use the OTU2 overhead at their respective ports to send a first custom identifier, for example, to send a first "sm tti test" identifier using the OTU2 SM TTI overhead. As an example, the first ASON network element and the second ASON network element are used. The "sm tti test" is sent over all ports A, B, C and D using OTU2 SM TTI. As port B and port D are directly connected to the third network element of the ASON and the first network element of the ASON, respectively, port B and port D can receive, respectively, the "sm tti test" sent by the third network element of the ASON and the fourth network element of the ASON. Therefore, OTU2 SM TTI tares of port B and port D can receive the "sm tti test". However, since the OTU2 SM TTI overhead cannot be transmitted transparently, port A cannot receive the "sm tti test" sent by the second ASON network element and port C cannot receive the "sm tti test "sent by the first ASON network element. In this way, the first ASON network element can determine that port A is connected to the network element of a third party network and / or the network element of the conventional network, and the second network element of ASON may determine that port C is connected to a third party network and / or to the network element of a conventional network.

Second, for port A and port C, the first ASON network element and the second ASON network element continue to send a second custom identifier using the ODU2 overhead, for example, to send a second identifier " pm tti test "+ port information using ODU2 PM TTI overhead. The port information may be a combination of a node identifier and a port identifier of a port, etc. As the ODU2 overhead can pass through a third-party network and / or the conventional network, if the ODU2 PM TTI overhead from port A can receive "pm tti test" + "port C information" from port C and overhead ODU2 PM TTI from port C can receive "pm tti test" + "information from port A" from port A, it can be determined that port A and port C are logically interconnected ports and there is a third party network and / or a Conventional network between port A and port C. In this case, port A and port C are logical remote interfaces for each.

Third, when it is determined that a third-party network and / or the conventional network connects port A and port C, and port A and port C are logical remote interfaces with each other, a TCM level can be configured for the ODU2 layers of port A and port C. Specifically an attempt is made starting with TCM 1. Port A and port C separately use the ODU2 TCM 1 TTI overhead to send a third identifier. The third identifier is, for example, "tcm tti test". If the ODU2 TCM 1 is not used in a network comprising the network element of a third-party network and / or the network element of the conventional network, the ODU2 TCM 1 TTI overhead of port C may receive the "tcm tti test "sent by port A, the ODU2 TCM 1 TTI overhead of port A can also receive the" tcm tti test "sent by port C, and this indicates that TCM 1 is an available TCM level. Otherwise, if port A cannot receive the "tcm tti test" sent by port C or port C cannot receive the "tcm tti test" sent by port A, this indicates that TCM 1 is not found available and it is necessary to continue with another attempt using another level of TCM.

It should be noted that in this embodiment, both port A and port C use TCM 1. However, in a real feasible form of implementation, the level of TCM used by port A and the TCM used by port C may be different.

Finally, after determining the level of available TCM, it is assumed that the first ASON network element determines that the first level of TCM is TCM 2, the TCM 2 of the ODU2 is used in port A and the port C, and is monitored if a link between port A and port C fails. When the link between port A and port C fails, rerouting starts quickly. Assuming that the first ASON network element determines that a second level of TCM is TCM 4, the tCm 4 of the ODU2 is used at port C and port A, and is monitored if the link between port C and port A. When the link between port C and port A fails, rerouting starts quickly.

FIG. 6 is a schematic diagram of the structure of a first embodiment of an ASON network element in accordance with the present invention. An ASON network element provided in this embodiment is an embodiment of equipment corresponding to the embodiment of FIG. 2 in the present invention. In the present application the details about the specific implementation process are not described again. Specifically, a network element 100 of an ASON provided by this embodiment includes:

a determination module 11, configured to determine whether a network element connected to the ASON network element 100 is a network element of a third party network and / or a network element of the conventional network;

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a configuration module 12, configured for, when the determination module 11 determines that the network element connected to the ASON network element is a network element of a third party network and / or a network element of the network conventional, configure a first level of joint connection monitoring (TCM) available for a higher order optical channel data unit layer k, where the first level of TCM is the same or different from a second level of TCM configured by a second network element of the ASON, and the network element of the third party network and / or the network element of the conventional network is connected between the network element of the ASON and the second network element of the ASON;

a monitoring module 13, configured to monitor, in accordance with the first level of TCM configured by the configuration module 12, if a link between the ASON network element and the second ASON network element fails; Y

a start module 14, configured to initiate rerouting when the monitoring module 13 detects that the link between the ASON network element and the second ASON network element fails.

The ASON network element provided in this embodiment of the present invention configures a first level of TCM after determining that a network element connected to the ASON network element is a network element of a third party network. and / or a network element of the conventional network; and monitors, according to the first level of TCM, if the link between the ASON network element and the second ASON network element fails. When it is determined that the link fails, rerouting begins to retrieve the link, which allows, in a hybrid network mode of an ASON and a third party network, rerouting is performed quickly when a third party network fails , in order to recover the link and ensure the quality of service.

FIG. 7 is an additional schematic diagram of the structure of an embodiment of a network element of the ASON in accordance with the present invention. As shown in FIG. 7, based on FIG. 6, the ASON network element in this embodiment includes, in addition:

a sending module 15, configured to send, using the overhead of a layer of optical channel transport unit k, a first identifier to the network element connected to the ASON network element, where

The determination module 11 is also configured to determine whether the overhead of an optical channel transport unit layer k of the network element can receive the first identifier sent by the sending module 15;

The sending module 15 is also configured for, when the determining module 11 determines that the overhead of the optical channel transport unit layer k of the network element cannot receive the first identifier, send, using the overhead of a layer of optical channel data unit k, a second identifier to the network element connected to the ASON network element, where the first identifier is the same as or different from the second identifier; Y

the determination module 11 is specifically configured for, when it is determined that the overhead of a layer of optical channel data unit k of the network element can receive the second identifier, determine that the network element is a network element of a third and / or a network element of the conventional network.

Optionally, in the previous embodiment, the sending module 15 is specifically configured to send a third identifier to a higher order optical channel data unit layer k of a second ASON network element using the first level of TCM; Y

the determination module 11 is also configured for, when it is determined that the upper order optical channel data unit layer k of the second ASON network element can receive the third identifier configured by the configuration module 12, determine that the first TCM is available.

Optionally, in the previous embodiment, the determination module 11 is also configured to, before the start module 14 starts the rerouting, determine if the optical order data channel layer k of the higher order of the element ASON network can receive a fourth identifier sent by the second ASON network element using the second level of TCM; Y

The monitoring module 13 is also configured for when the determination module 11 determines that the upper order optical channel data unit layer k of the ASON network element can receive the fourth identifier sent by the second element ASON network using the second level of TCM, monitor, according to the second level of TCM, if a link between the second ASON network element and the ASON network element fails.

FIG. 8 is a schematic diagram of the structure of a second embodiment of a network element of an ASON according to the present invention. As shown in FIG. 8, an ASON network element 200 provided in this embodiment includes a processor 21 and a memory 22. The ASON network element 200 may further include a transmitter 23 and a receiver 24. The transmitter 23 and The receiver 24 may be connected to the processor 21. The transmitter 23 is configured to send data or information, the receiver 24 is configured to receive the data or information, and the memory 22 stores an execution instruction. When the network element 200 of the ASON operates, the processor 21 communicates with the memory 22, the processor 21 invokes the execution instruction in the memory 22 to execute the method execution mode shown in FIG. 2. An implementation principle and its technical effect are similar, and the details in the present application are not described again.

A person with a normal knowledge in the art can understand that all or a part of the steps of the methods of realization of the method can be implemented by means of a program that manages the appropriate hardware. The program can be stored in a storage medium readable by a computer. When the program is executed, the steps of the method realization modes are performed. The above storage medium includes: any medium that can store program code such as a ROM, a RAM, a magnetic disk or an optical disk.

Finally, it should be noted that the above embodiments are only intended to describe the technical solutions of the present invention, but not to limit the present invention. Although the present invention is described in detail with reference to the above embodiments, people 20 with a normal knowledge in the art should understand that they can still make modifications to the technical solutions described in the above embodiments or make equivalent substitutions to some or all its technical characteristics without departing from the scope of the technical solutions of the embodiments of the present invention.

Claims (7)

5 10 fifteen twenty 25 30 35 40 Four. Five fifty 1. A rerouting method, comprising: determine (101), by a first network element of an automatically switched optical network, ASON, if a network element connected to the first ASON network element is a network element of a third-party network and / or a network element of the conventional network; configure (102), by the first ASON network element, a first level of joint connection monitoring, TCM, available for a higher order optical channel data unit layer k of the first ASON network element if the network element connected to the first ASON network element is a network element of a third party network and / or a network element of the conventional network, where the first level of TCM is the same as or different of a second level of TCM configured by a second ASON network element, and the network element of a third party network and / or the network element of the conventional network is connected between the first ASON network element and the second ASON network element; monitor (103), by the first ASON network element, according to the first level of TCM, if a link between the first ASON network element and the second ASON network element fails; and initiate (104), by the first ASON network element, rerouting if the link between the first ASON network element and the second ASON network element fails; wherein the determination, by a first network element of an automatically switched optical network, ASON, of whether a network element connected to the first ASON network element is a network element of a network element of the network of a third party and / or a network element of the conventional network comprises: sending (201), by the first ASON network element, using the overhead of an optical channel transport unit layer k, a first identifier to the network element connected to the first ASON network element; determining (202), by the first ASON network element, whether the overhead of an optical channel transport unit layer k of the network element connected to the first ASON network element can receive the first identifier; if the first ASON network element determines that the overhead of the optical channel transport unit k layer of the network element connected to the first ASON network element cannot receive the first identifier, send (203), by part of the first ASON network element, using the overhead of a layer of optical channel data unit k, a second identifier to the network element connected to the first ASON network element, where the first identifier is the same that or different from the second identifier; Y determine (204), by the first ASON network element, whether the overhead of the optical channel data unit layer k of the network element connected to the first ASON network element can receive the second identifier, and If the overhead of the optical channel data unit layer k of the network element connected to the first ASON network element can receive the second identifier, determine that the network element connected to the first ASON network element is a network element of a third party network and / or a network element of the conventional network. 2. The method according to claim 1, wherein the configuration, by the first ASON network element, of a first level joint connection monitoring, TCM, available for a layer of optical channel data unit k higher order of the first ASON network element if the network element connected to the first ASON network element is a network element of a third party network and / or a network element of the conventional network comprises: sending, by the first ASON network element, a third identifier to a higher order optical channel data unit layer k of the second ASON network element using the first level of TCM; Y determine, by the first ASON network element, if the upper order optical channel data unit layer k of the second ASON network element can receive the third identifier, where the third identifier can be received , the first level of TCM is available. 3. The method according to any one of claims 1 to 2, wherein before initiating, by the first ASON network element, rerouting if the link between the first ASON network element and the network fails. ASON's second network element, the method also includes: 12 5 10 fifteen twenty 25 30 35 40 Four. Five fifty determine, by the first ASON network element, if the upper order optical channel data unit layer k of the first ASON network element can receive a fourth identifier sent by the second ASON network element using the second level of TCM; Y if the fourth identifier can be received, monitored, according to the second level of TCM, if a link between the second ASON network element and the first ASON network element fails. 4. A network element of an automatically switched optical network, ASON, comprising: a determination module (11), configured to determine whether a network element connected to the ASON network element is a network element of a third party network and / or a network element of the conventional network; a configuration module (12), configured for, when the determination module determines that the network element connected to the ASON network element is a network element of a third party network and / or a network element of the conventional network, configure a first level joint connection monitoring, TCM, available for a layer of unit k of higher order optical channel data, where the first level of TCM is the same as or different from a second level of configured TCM by a second network element of the ASON, and the network element of the network of a third party and / or the network element of the conventional network is connected between the network element of the ASON and the second network element of the ASON; a monitoring module (13), configured to monitor, in accordance with the first level of TCM configured by the configuration module, if a link between the ASON network element and the second ASON network element fails; Y a start module (14), configured to initiate rerouting when the monitoring module detects that the link between the ASON network element and the second ASON network element fails; where the ASON network element also includes: a sending module (15), configured to send, using the overhead of a layer of optical channel transport unit k, a first identifier to the network element connected to the ASON network element, where The determination module (11) is also configured to determine whether the overhead of an optical channel transport unit layer k of the network element connected to the ASON network element can receive the first identifier sent by the module Shipping; The sending module (15) is also configured for when the determination module (11) determines that the overhead of the optical channel transport unit k of the network element connected to the ASON network element is not it can receive the first identifier, send, using the overhead of a layer of optical channel data unit k, a second identifier to the network element connected to the ASON network element, where the first identifier is the same as or different of the second identifier; Y the determination module (11) is specifically configured to, when it is determined that the overhead of a layer of optical channel data unit k of the network element connected to the ASON network element can receive the second identifier, determine that the Network element connected to the ASON network element is a network element of a third party network and / or a network element of the conventional network. 5. The network element according to claim 4, wherein: the sending module (15) is specifically configured to send a third identifier to a higher order optical channel data unit layer k of the second ASON network element using the first level of TCM; Y the determination module (11) is also configured for, when it is determined that the upper order optical channel data unit layer k of the second ASON network element can receive the third identifier configured by the configuration module , determine that the first TCM is available. 6. The network element according to any one of claims 4 or 5, wherein: the determination module (11) is also configured to, before the start-up module (14) starts the rerouting, determine if the upper order optical channel data unit layer k of the ASON network element You can receive a fourth identifier sent by the second ASON network element using the second level of TCM; Y The monitoring module (13) is also configured for when the determination module (11) determines that the higher order optical channel data unit layer k of the ASON network element You can receive the fourth identifier sent by the second ASON network element using the second level of TCM, monitor, according to the second level of TCM, if a link between the second ASON network element and the network element fails ASON network. 7. A network element of an automatically switched optical network, ASON, comprising a receiver (24), a transmitter (23), a processor (21) and a memory (22), where memory stores an execution instruction, and when the ASON network element is operating, the processor communicates with the memory and the processor executes the execution instruction to allow the ASON network element to execute the method according to any one of claims 1 to 3.